Probing the physical conditions and star formation processes in the Galactic HII region S305

TL;DR

This study combines multi-wavelength observations to analyze the physical conditions, star formation processes, and feedback effects of O-type stars in the Galactic HII region S305, revealing complex structures, molecular dynamics, and non-thermal emissions.

Contribution

It provides a detailed multi-scale, multi-wavelength analysis of S305, highlighting the feedback of massive stars and the structure of the surrounding molecular environment, which is novel in its comprehensive approach.

Findings

Detection of an extended shell structure around S305

Evidence of an expanding molecular shell and feedback effects

Observation of non-thermal radio emission with variable spectral index

Abstract

We present multi-scale and multi-wavelength observations of the Galactic HII region S305, which is excited by massive O8.5V and O9.5V stars. Infrared images reveal an extended sphere-like shell (extension ~7.5 pc; at T_d = 17.5-27 K) enclosing the S305 HII region (size ~5.5 pc; age ~1.7 Myr). The extended structure observed in the Herschel temperature map indicates that the molecular environment of S305 is heated by the massive O-type stars. Regularly spaced molecular condensations and dust clumps are investigated toward the edges of the infrared shell, where the PAH and H_2 emission is also observed. The molecular line data show a signature of an expanding shell of molecular gas in S305. GMRT 610 and 1280 MHz continuum maps reveal overdensities of the ionized emission distributed around two O-type stars, which are surrounded by the horseshoe envelope (extension ~2.3 pc). A molecular gas deficient region/cavity is identified toward the center of the horseshoe envelope, which is well traced with PAH, H_2, molecular, and dust emission. The edges of the infrared shell are found to be located in the front of the horseshoe envelope. All these outcomes provide the observational evidence of the feedback of O-type stars in S305. Moreover, non-thermal radio emission is detected in S305 with an average spectral index alpha ~-0.45. The variations in alpha, ranging from -1.1 to 1.3, are explained due to soft synchrotron emission and either optically-thicker thermal emission at high frequencies or a suppression of the low-frequency emission by the Razin-Tsytovich effect.